Convection and forced draft air flow and combustion air heating furnace



Feb. 21, 1950 R. w. DE LANCEY CONVECTION AND FORCED DRAFT AIR FLOW AND COMBUSTION AIR HEATING FURNACE 6 Sheets-Sheet 1 Filed Nov. 13, 1943 100 m4 I00 95 I006 INVENTOR PAL/9H W DELANCEY ATTORNEY Feb. 21, 1950 R w. DE LANCE Y 2,498,362 CONVECTION AND FORCED DRAFT AIR FLOW AND COMBUSTION AIR HEATING FURNACE Filed Nov. 13, 1943 '6 Sheets-Sheet 2 INVENTOR mu? W DELA/VCEY ATTO R N EY Feb. 21, 1950 R. w. DE LANCEY 2,498,362.

CONVECTION AND FORCED DRAFT AIR FLOW I AND COMBUSTION AIR HEATING FURNACE Filed Nov. 13, 1945 6 Sheets-Shut 5 U-- INVENTOR RALPH 1 1 DELANCEY ATTORN EY Feb. 21, 1950 R. w. DE LA cEY CONVECTION AND FORCED DRAFT 2,498,362 AIR FLOW AND COMBUSTION AIR HEATING FURNACE 6 Sheets-Sheet 4 Filed Nov. 13, 1943 INENTOR RALPH WDELANCEY 5% m T WWW I ATTO R N EY Feb. 21, 1950 R. w. DE LANCEY CONVECTION AND FORCED DRAFT AIR FLOW AND COMBUSTION AIR HEATING FURNACE 6 Sheets-Sheet 5 Filed Nov. 13, 1945 INVENTOR RALPH, W DELANC'EY ATTORNEY n 2 6 C 6 N I 3 a .mM H Rm e TH N 9 ND R 4 w m 2 MN NW N m H s M e P m Feb. 21 1950 R. w. DE LANCEY I CONVECTION AND FORCED DRAFT AIR FLOW Agm COMBUSTION AIR HEATING FURNACE Filed Nov. 13, 1943 Patented Feb.v 21,- 1950 UNITED sm'res PATENT omce l" t 3 2,498,362

CONVECTION AND FORCED DRAFT AIR FLOW AND COMBUSTION AIR HEATING FURNACE Application November 13,1943, Serial Na 510,181

10 Claims. (Cl. 12.6110) The present inventionrelates to Warm air; heating furnaces and is more particularly directed toward portable Warm air furnaces.

Extremely cold weather, such as 40 degrees below zero Fahrenheit, and colder, is found dur- 5 At extremely low temperatures it is ing the winter in very cold climates, and this for the operatorto avoid exposing his hands as temperature is so low as to call for auxiliary much as possible and avoid contact of the bare heating to make it possible to start automotive hands with exposed parts. According 'to "the" equipment, such as automobiles, trucks, tanks, present invention, the controls for the furnace tractors, airplane engines and the like, and the are designed so that every manipulationnees-Q present invention is more especially directed sary in getting the burner into operation toward warm air heaters which areysuitablefor be done by the mittened hand, except for the. heating such equipment to a sufficient amount striking of the match to ignite the torch. This to make it possible to start the equipment in makes it possible for the operator to do all the the same mazmer as during warm weather. At 16 manipulations necessary except ior'the more} low tempera ures, such as referredto, lubri-, lighting of, the match while keeping on his mit-;- eating oils and greases are extremely stiff and tens. batteries are very weak, so that ordinary crank- In the more usual types of construction ins o s Cannot b employed- Flllthermore; wherein oil is burned in vaporizing type burners; highly volatile fuels give off so little vapor as to 2o 11; i ery im ortant that the burner and parts; be t pabi e Oil ?i ignitedh y the igtnition associated with it be very carefully levelled sys ems or man y use on suc equipmen Accordin to the resent invention, h wever, the According to the present invention a burner aid assoc iated controls are onstructed pa y small po t b e heater which can burn in such a manner that levelling of the burner gasoline, Diesel fuel oil, orlighter heating oils, 25, is not e m and as a matter of fact, thei is employed to heat a blas f a which is blown entire furnace and associated burner operate n to the eclnlpmnnt be warmed; Where entirely satisfactorily at very substantial angles" inc power 15 evaluable for Opemimg an elecmc of tilt in any direction. This makes it possible": gif g fii iggf i s f i b to operate the burner and furnace when icon-i. o. e, to r,ecr1c 1 I power is not available (and. at these low tem- 5 22 2 3 igg i g lg g gg h on pemtures battery power is not Satisfactory) While the hot air furnace shown-and described combustion engine f' herein in detail is more-especially suitable for! P t i f gtfg ET use under the conditions above referred to,-.it is: nci ait" antic iatiiaiih thiiltt piistii suiiebleforuse1mmStationeryhotairheteelf invention contemplates that the fuel will be moblle i portable heaters dehydratm'sj ignited from a torch (lighted by a match) and and h hke wlthmlt changes'necessary the burner operated under natural draft conditions for a time sufiicient to Warm the burner 0 m and further Q W111 appear fl and the small internal combustion engine, and descnptlon proceefis- I then the operation of the burneris changed from T m a i r n PW e esg natural draft operation to forced draftv opera of illustrating the present invent1on an embodrtion as soon as the blower can be started. M ment In wnlch e t tio may take form, 7 While some heating applications such as the 5 together with modifications of certain parts, Warming of autemotive equipment can be Carried being understood that the drawings are illustra out by the use of contaminated hot air, other tlve of the'lnvemlon a r t llmlimg the" heating operations such, for example, as the Sameheating of compartments occupied by personnel, H In Pnese drawings; I such as cabs and trailers, must be carried out by Figure 1 is diagrammatic exploded View -L pure fresh air, and the present invention Con-2 trailing Sub-assemblies for thecomplete e; templates providing the hot i air furnace with the subordinate views being taken from the front suitable means whereby pure uncontaminated Side Of the ac I ,1 air may be delivered or whereby the air delivered Figure 2 is an exploded view similar to Figure I, contains the products of combustion as wellyas u but with the subordinate views taken from the,

the air blown through the f urnaceby the fan;

This contaminated air will, of course, delivera" much greater heat output than that available with uncontaminated air, only.

necessary right hand end of the furnace parts, as viewed in Figure 1;

Figure 3 is a front side elevational view of the hot air furnace arranged for delivering contaminated air and showing the controls (all of which are in thenormal running position), also the use of an electric motor operated blower;

Figure 4 is a side elevational view taken opposite to the view of Figure 3 and showing the furnace arranged for delivering pure fresh air and with an internal combustion engine driven fan; i

Figure 5 is a longitudinal sectional view taken in the same direction as Figure 4, and on the vertical center line 5-5 of Figures'9, 11 and 12, the parts being arranged for delivering contaminated air; 5 I

Figure 6 is a transverse vertical sectional view on the line 6-45 of Figure 5 looking in "the di-' rection of the arrows and showing the constant level valve, the metering valve and associated controls, all in the normal running Position;

Figure '7 is a plan view taken in the direction of the arrows I of Figure 6;

Figure 8 is a sectional view on the line B-8 of Figures 6 and 7, the parts being indicated in the shut down position by dotted lines;

Figure 9' is an inverted plan view with parts broken away to show interior construction and parts in section on the line 99 of Figure -5;

Figure 10 is a fragmentary view illustrating a detail of the combustion drum and air tubes;

Figure 11 is an elevational' view taken from the right of Figure '3 and the left of Figures and -5 with parts broken away to show interior construction, the air temperature responsive thermostat being cold;

Figure 12 is an end elevational view taken fro the right of Figure 4 with parts broken away to show interior construction and the furnace arragned to deliver pure heated air;

Figure 13 is a fragmentary view showing the lightingdoornpen; and

Figure '14 is .a fragmentary sectional-view showing a modified form of thermostat adjustment.

Reference is first made to Figures 11 and 2, which diagrammatically show the sub-assemblies for a complete portable hotrair furnace, designed for heating automotive equipment. The bottom housing unit is shown at A. The combined fuel burner constant IevelyalVe-metermg valve-and valve control unitis shewnat B. Thislatter unit ismounted under the bottom housing and in turn carries a bottom closure cup B". The combus-v tion drum C is received in the bottom housing A and covered by the .top housing .D. Thestack for the discharge of products of combustion from the combustion drum is indicated at E ancithe cap by which the stack may be; closed off is indicated at F. A plug by which the left end of the combustion drum CLmay be closed .,or opened is indicated at G, and a discharge or air delivery cover is indicated at .H. The .fuel supply tank carried on top of the top housing. is indicated at I; the strainer .at J, and the pipes for intercon necting the fuel tank with strainer and the I strainer with the constant level valve atK. The

air temperature responsive thermostat for con trolling the metering valveiis shown at L, the blower at M and the bimetallic safetyat N, Some of the smallerparts employed in asseme bling the furnace are omitted from Figures 1 and 2. v I

The bottom housing unit "A" has a -semi-cylindrical bottom "housing member, to which is welded a tubular burner housing 2|. This burner housing tube extends below the bottom housing member as indicated at Ma, Figure 5, and above it as indicated at Zlb. The unit A also has legs 22 for support.

The combustion drum C has an outer cylindrical body 24, and end walls 25 and 2B. These end walls have aligned openings 21, which receive air tubes 28. The bottom part of the drum body 24 is provided with an opening 29 in which is welded a downward extending fire tube 30. It

will be noted from the drawings that this fire tube is near one end of the combustion drum and that the lower air tubes 28 are spaced apart substantially the same distance as the diameter of the fire tube 30. The adjacent wall 25 of the combustion chamber supports an inverted boxlike bafile 3|, made of perforated sheet metal and shown more clearly in Figures 5 and 11. This perforated baflie protects the adjacent ends of the air tubes 28 from direct impingement of the flame and yet permits the heat to pass out about these air tubes. The bafiie 3| has a downwardly sloping cross baifie '31 which compels most of the heated air to pass out underneath it. The combustion drum is provided with a stack opening 32 at the top and at the end opposite the fire tube 30. The outside of the combustion drum is provided with sheet metal strips 33, to provide air passages 34 and fins 35. The combustion drum C can be completely assembled and lowered into position in the bottom housing A with the fire tube 3! concentric with the tubular burner housing 2|, and then the lower strips 33 will rengage the inner surface of the bottom housing member 2|) to provide longitudinally extending air passages in the space between the combustion drum and the bottom housing. The upper edge of the tube 2| engages the lower surface of the drum 24 in the side away from the end wall :25 so as to provide an opening .31 for supplying air to the burner. A short tube 38 is welded into the stack opening 32. The strips 33 which extend along the center of the drum are provided with reinforcing bars '39., 39, see Figures 9, 1i and 12.

The top housing unit D has a semi-cylindrical top .housing member 40, similar to the bottom The stack E may assume various forms, but a I convenient form is shown in the drawings as consisting of a vertical tubular element 43 and horizontal tubular element it, these being Welded together. The vertical part of the stack may telescope down into stack tube 38, so that the stack may be turned to discharge products of combustion in various directions. The cap F for the stack merely fits on the outer end of the stack and may either be placed in the stack or hung free by means of the chain 45 shown.

When the cap is in the position indicated in Figures 4 and 12, the products of combustion pass out through the stack, but when it is in the positionind-icated in Figure 3 products of combustion do not pass out through the stack. In order to permit the products of combustion to escapeirom the drum without going up the stack, the end wall'26 of the drum is provided with flanged opening adapted to receive and support the plug G. This plug element comprises a cup shaped stamping 47, having a closed end wall and a stamping 48 having a large central opening 48', these stampings being held together by straps 49. The stamping 48 has an outwardly flared rim 50. When the plug is in the position shown in Figures 4, 9 and 12, the cup shaped stamping 41 is inserted into the opening 46 in the end wall'of the combustion drum and compels the products of combustion to go up through the open stack. When, however, the plug G is withdrawn and reinserted with the stamping 48 held in place in the flanged opening 46, as shown in Figure 5, the products of combustion may pass through the hole in the stamping 48 and enter the plug. This plug acts differently than would a mere damper, for the plug intercepts sparks so that they cannot pass out into the hot air stream, and it also prevents back pressure choking off the escape of the products of combustion. Also I the gases do not pass directly through the plug but instead escape out through the space provided by the enlarged rim 50 of the stamping 48 and therefore are diffused into the air blown out through the tubes 28. In order to prevent loss of the plug, it is secured to the combustion drum by a chain 5|.

The air delivery cover H shown herein is one adapted to receive a duct, usually of fabric, for conducting air to the region to be heated. It is shown as a cylindrical sheet metal device hinged at 52 and provided with a catch 53. It serves to receive the air blown through the combustion drum and the space between the combustion drum and the housing, as well as the contaminated air when the plug G and the cap F are in proper position" for delivering contaminated air.

In the form shown in Figures 1 through 12, the cover member H can be lowered about the hinge as shown in drawings. A modified form of cover is illustrated in Figure 14 and will be later described.

In order to provide a blast of air through the furnace the open rear end of the housing accommodates a blower M which may be either an electric motor and fan as indicated at 54, Figure 3, or an internal combustion engine and fan as indicated at 55 in Figure 4. The fuel for the engine may be obtained from a small tank forming part of the engine unit, as indicated, or from the burner supply tank I where gasoline is used as a fuel. Where the latter is used a starting pulley 56 is placed beyond the end of the housing. The blower unit not only blows air through the tubes 28 to be heated, but also causes a blast of air to pass down through the space between the fire tube 30, and the tubular burner housing 2| to supply the burner. A deflector 51 is employed to guide a portion of the blast of air from the fan into this down draft passage.

The fuel supply tank I is shaped to be mounted on top of the housing and as here shown extends from the rear end of the housing nearly to the stack. It extends about the sides of the top of the housing and is suitably secured to brackets 68 carried by the housing. The tank is provided with a handle Bl by which the entire furnace can be carried. The liquid fuel carried in this tank is delivered to the strainer J through pipes 82 and 63. These two pipes are connected to the diagonally opposite corners of the tank, so that fuel can be drained from the tank when the furnace is substantially out of level.

The" strainer J may be of conventional construction and may be secured in anyconveni'ent way to the bottom of the housing. It carries a shut off valve 64, biased to closed position and operable to an open position by a lever 85. The discharge pipe from the strainer is indicated at 66 and it leads into the fuel control valve formed in part of the burner control valve unit B.

The body casting of the burner valve control unit B is designated by the reference character). It has a float chamber H which is closed off by a cover 12, fastened in place by screws 72'. The cover has a rearwardlly extending tubular coupling element 13 for coupling to the fuel line 66. A valve seat member 74 is threaded up into a drilling 14' in the cover member 12 and this valve seat member 74 receives a valve pin 15 which is normally controlled by a float I6 hinged at H. When the parts are in the position shown in Figure 6 the float l6 and float control valve 15 operate similarly to thefloat valve in an automobile engine carburetor and maintain a predetermined supply of fuel in the float chamber H. The casting 10 is provided with an outlet valve seat insert 18 at the bottom of the float chamber, which cooperates with a metering valve stem 19 urged upwardly by a spring and downwardly by mechanisms to be described; This valve forms the metering valve for the burner.

The constant level valve and metering valve are under manual control for the purpose of starting and stopping the burner and are under automatic control for the purpose of emergency shutdown of the burner as well as for the continuous control of the metering valve for normal continuous operation. These form the subject matter of my applications Serial Nos. 510,183 and 510,184, respectively, filed concurrently herewith, which have been issued as Patents No. 2,447,902, dated August 24, 1948, and No. 2,428,867, dated October 14, 1947, respectively. These controls will now be described. i

The starting lever for opening the fuel line into the fuel chamber H is shown at 8|. It is pivoted at 82 to the U-shaped stamping 82' carried by the cover member and has a general horizontally extending arm 83, which overlies the top of the cover member 12. When it is in the position shown in Figures 3 to 8 and 11, the inner end of this arm 83 is latched in this position by a lever 84 pivoted at 85 to the stamping 82' and having a rear extension 88.

When the starting lever B! is latched in this normal operating position, the arm 92 presses down on a pin 81 which extends through the float chamber cover 12 and normally rests on the top of a leaf spring 88. This leaf spring is carried by the under side of the cover 12 and is normally urged upwardly. It is arranged as shown in'Figure 6 to be free of the float mechanism when in that position, but when the starting lever 8| is in the shut off position, as indicated in dot and dash lines in Figures 5 and 8,'the pressure on the leaf spring 88 is removed and this spring is able to act on the float mechanism, so as to move it into the position to move the valve 15 to closed position and at the same time it will lock the float mechanism against vibration during shipment or transportation of the burner.

The starting lever 8| has a cam 89 (see Figure 8) adapted to act on a lever 90 pivoted to the stamping 82 at 9| and urged downwardly by a coiled spring 92. The lever 9|] carries a leaf spring 93 whose position can be adjusted by high fire adjustment screw 94. The free'end of the spring 93 extends above shoulder 95 on the valve 9 metering valve can not be closed by the operation of the thermostat MI. The stop I54 limits the movement of the parts operated by the thermostat HH and does not permit the pivot point between the parts I41 and I to pass a lower dead center.

When the furnace is in continuous operation the thermostat I II operates back and forth between the position where it permits high or maximum high fire operation and th position where it allows only pilot operation. The intensity of the fire, therefore, varies between the maximum and minimum, so that there is no likelihood of overheating the parts, or delivering the air at too high a temperature, or of extinguishment of the flame.

In the form shown in Figure 14 the shaft I40 carrying the bimetallic coiled thermostat MI is provided with a yoke I55, and this yoke is connected through universal joint connections I56 with a shaft I51. This shaft extends out through a guide tube I58 carried by the discharge or air delivery cover I59 (similar to the cover H, but not hinged). The tube I58 carries a spring casing member I60 and an operating handle I6I. The casing I60 can be secured to the shaft I 51 in any desired position by a lock screw I62 and a spring I63 forces the handle I6I toward the walls of the cover I59. To keep the arm I6I in adjusted position it is provided with a boss I64 adapted to enter into selected openings around the axis of the shaft I51. When the device of Figure 14 is first assembled adjustments are made when the screw I62 is loose. The handle I6I is then placed in its proper positon and the screw I 62 tightened, after which adjustments of the thermostat may be made at will to vary the temperature of the air delivered without disturbing any of the other parts of the device.

It will thus be seen that when the structure is cold or at ordinary room temperatures the extent of opening of the metering valve will be controlled by the adjustment of the stop mechanism for the air temperature responsive thermostat, and that when the starting lever 8| is moved to the starting position the fuel line will be opened to the float chamber, and fuel at a predetermined flow rate will pass down to the burner. This fuel will form a pool in the burner and must be immediately lighted. If for any reason the metering valve is allowed to remain open too long before the torch is supplied, the oil can flow from the vaporizer out through the tube I 01 and escape through a drain hole I22 in the stamping I22. The lighting can be done by inserting a torch T (such as indicated in Figure 3) through the lighting tube I30. The fuel will be consumed in the burner and the natural draft caused by the combustion of the fuel will cause the products of combustion to pass up through the combustion drum, and air will be drawn in through the down draft tube 2I. When the burner has been heated by natural draft sufficient to permit forced draft operation, the motor or engine may be started so as to operate the fan and blow air through the furnace and through the burner.

When the furnace is to be operated at extremely low temperatures such as 40 below zero the internal combustion engine for operating the fan can not be started by ordinary cranking methods, but it can be preheated by the present apparatus, using the apparatus as a temporary natural draft burner. During operation at natural draft the drum end wall is heated and it radiates heat toward the engine. For more quickly pre-heating the internal combustion engine, the entire furnace is preferably tilted, as indicated in Figure 4, to raise the rear end having the engine above the front or output end of the furnace as indicated by the dot-anddash lines in the upper left-hand corner of Figure 4. The operation of the burner under natural draft will heat the combustion drum and the naturally induced air currents which pass through the air tubes 28 which extend through the combustion drum will cause ascending currents of warm air to pass by the internal combustion engine and warm it. Soon it can be started by th usual pulley and rope arrangement employed for such small engines, whereupon the burner will at once change over in its operation to forceddraft.

The maximum combustion rate of the burner under either natural draft or forced draft is greater than the capacity of the metering valve to deliver fuel, so that there is no substantial accumulationof fuel in the vaporizer. The fuel which passes through'the metering valve runs down through the tube I05 without filling-it: The continued operation of the. burner under forced draft will cause the combustion chamber to get-hotter. and the air in the airtubes to increase in temperature and this will bring about the heating of the air temperature control th er-' mostat I so as to cause the metering valve controlling mechanism to move upwardly, so that the metering valve can open wider than it could when the apparatus was cold. This will increase the firing-rate to an amount determined by the adjustment of nut 94. The further increase in temperaturewill merely shift theair temperature control thermostat MI to bring the parts past dead center and the slider I49 back down toward the metering valve stem. When it engages the metering valve stem, it will start to close off the flow of fuel to the burner. The extent of closing movement of the metering valve will be insufficient to completely out off the fiow of fuel and extinguish the burner. The apparatus which has been shown herein for controlling the metering valve is one which normally moves the metering valve stem back and forth between low fire and a much higher fire.

The flow rate of a metering valve at any selected adjustment varies very widely over ranges of temperature from 40 F. to room temperatures vso that an adjustment for the very low temperature would allow a great excess of fuel to fiow' at the higher ambient temperature. By

having the metering valve move back and forth it is possible to have the maximum flow rate when operatingfor a high temperature rise of the air forced through the furnace and to rely on the thermostatto reduce the flow rate to the fine sieve in the strainer. Some of these crystals pass into the float chamber and tend to'accumulate about themetering valve stem and to clog the orifice of the metering valve stem, especially when the stem is fixed. By moving the stem back and forth these crystals are crushed and pushed through the orif ce. When the float chamber warms up the ice crystals melt so as to form small dropletsof water. These tend to move toward themetering valve stem slot and are forced 13 end of the drum toward the open end of the housing remote from the stack outlet to provide a down draft passage for air for the burner which passage opens under the end of the drum, a blower unit in the latter mentioned end of the horizontal housing for normally blowing air toward the adjacent said end of the drum and into the opening for the draft passage to provide forced draft, and through said annular space unoccupied by the burner housing for cooling the outside of the drum, the drum also having horizontal air tubes through which the blower unit blows air, the air tubes and the drum-housin space opening into the other end of the tubular housing, the heater when operating under natural draft conditions heating the end of the drum adjacent the blower unit hotter than the other end and bringing about a natural circulation of air from the combustion drum toward the blower unit to preheat it as well as the air taken in by natural draft, whereby the blower unit may be preheated and started so as to provide the forced draft and forced air circulation.

6. In a hot air furnace, a lower semi-cylindrical housing part open at both ends to provide an air inlet and an air outlet and having a downwardly extending tube substantially midway of its length, the side of the tube remote from the inlet end of the housing having a portion extending up wardly into the housing, a cylindrical combustion drum of smaller diameter than the housing part and downwardly receivable in said lower housing part with its lower wall engaging the upwardly extending portion of the tube to form a baflle across the space between the housing and drum, the drum having a fi-re tube concentric with and smaller than said tube to form an annular passage, a plurality of horizontally extending air tubes and a stack opening at the top, an upper semicylindrical housing part secured to the lower part about the drum and carrying a stack extending down into the stack opening in the drum, a burner carried by the outer tube under the fire tube and discharging the products of combustion through the fire tube into the drum, and a blower in the inlet end of the housing for forcing air through the air tubes, the annular passage and into the burner, and for forcing the products of combustion through the fire tube, the interior of the drum and the stack.

7. A hot air furnace comprising a horizontal tubular housing having an inlet end and an outlet end, a power operated fan received in the inlet end of the housing for blowing air towards the outlet end of the housing, a drum having an outer wall spaced from the housing wall, and disposed toward the outlet end of the housing, the drum having spaced end walls connected by peripherally disposed horizontal air tubes whereby the air blown by the fan escapes through the air tubes and the drum-housing space, a short fire tube extending downwardly from the drum through the bottom of the housing and disposed at the end of the drum near an inlet end of the housing, a burner below the tube and discharging flame and hot products of combustion into the fire tube and drum, means for intercepting a portion of the air forced through the drum-housing space and for conducting it to the burner to afford forced draft, and a stack extending from the top of the outlet end of the drum through the top of the housing.

8. A hot air furnace as claimed in claim 7, having a perforated flame impingement baflle of inverted channel shape between the air tubes and the discharge end of the fire tube.

9. A hot air furnace as claimed in claim 7, having a plug insertible in the stack and a removable closure for an opening in the end wall of the drum adjacent the stack, whereby the products of combustion may escape through the opening.

10. A hot air furnace as claimed in claim 7, wherein the discharge end of the drum has a central opening to allow escape of products of combustion to mix with the fresh air coming through the tubes and drum-housing space, and a deflector for spreading the discharged combustion gases to mix them with the fresh air.

RALPH W. DE LANCEY.

REFERENCES CITED The following references are of record in the file of this patent:

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